Flat top, double-angled, wedge-shaped fiber endface

ABSTRACT

An improved fiber endface shape for increasing coupling of optical power from a source into fiber and its manufacture are disclosed. The inventive tip comprises a cleaved end surface that is preferably substantially orthogonal to the fiber&#39;s axis and a first and second polished, angled surfaces intersecting the end surface. Break-lines between the angled surfaces and the end surface fall near an edge of a cladding-core interface and preferably outside that interface when the fiber and transmitted light are such that a substantial portion of the light is transmitted in the cladding. A spatial intensity profile of light exiting from the tip is detected during manufacture and is used to monitor the polishing of the angled surfaces. Tests have shown that the inventive tip achieves the coupling efficiency associated with the double-angled wedge-shaped fiber tips while maintaining much of the ease of manufacture associated with the single-angle wedge tips.

RELATED APPLICATION

This application claims priority to U.S. provisional application No.60/048,573, filed Jun. 4, 1997, the entire teachings of which areincorporated herein by reference.

BACKGROUND OF THE INVENTION

In optical fiber communication systems, and optical fiber lighttransmission systems generally, it is typically important to increasethe efficiency with which light from a source is coupled into the fiber.One of the most common applications is in communications systems tocouple light from a single-transverse-mode light source, e.g.,semiconductor laser, into a single-mode optical fiber. Historically,there has been a trade-off between high coupling efficiency and ease ofmanufacture. The following examples illustrate this principle:

1. Bulk optics

This is a popular technique in which lens are used to focus the lightfrom the semiconductor laser onto the endface facet of the fiber. It canprovide high-coupling efficiency if adequate lenses are used. The factthat multiple components, typically 1 or 2 lenses, are needed greatlyincreases the complexity of implementation and the reliability risk,however.

2. Hyperbolic fiber endfaces

The technique has provided coupling of 99% of the power from asingle-mode laser into a single-mode fiber by using a high-powerinfrared laser to machine a hyperbolic surface on the fiber endface ortip. A hyperbola is the ideal shape for fiber coupling. Unfortunately,it is extremely difficult to accurately manufacture these fiber tipswith sufficient yield that would warrant implementation in large-scalemanufacturing of fiber-coupled single-mode laser modules.

3. Single-angle wedge-shaped fiber endfaces

This has been used to couple 980 nanometer pump lasers to single-modefibers. While it has the positive feature of being easy to manufacture,the achievable coupling efficiency has been limited to between 65 and70%.

4. Double-angled wedge-shaped fiber tips

This technique is a compromise between hyperbolic fiber endfaces and thesingle-angle wedge-shaped fiber endfaces described above. It provideshigher coupling efficiency than single-angle wedge-shaped endfaces, butnot as high as hyperbolic endfaces. It is significantly easier tomanufacture and implement than hyperbolic endfaces, but not as easy assingle-angle wedge-shaped fiber endfaces. To completely specify andmanufacture the double-angled wedged-shaped fiber tip, four independentangles, having one of only two different values, and the location ofthree lines of intersection must be fabricated with sufficientprecision.

SUMMARY OF THE INVENTION

The present invention is directed to an improved fiber endface shape andits manufacturing process. It achieves the coupling efficiencyassociated with the double-angled wedge-shaped fiber tips whilemaintaining the ease of manufacture associated with the single-anglewedge tips.

In general, according to one aspect, the invention relates to opticalfibers, which include a core and surrounding cladding for transmittingelectromagnetic radiation, and specifically the tips or endfaces thatusually receive input radiation from a light source. The inventive tipcomprises an end surface that is preferably substantially orthogonal tothe axis, a first angled surface intersecting the end surface, and asecond angled surface also intersecting the end surface.

In the preferred embodiment, break-lines between the angled surfaces andthe end surface fall near an edge of a cladding-core interface andpreferably outside that interface when the fiber and transmitted lightare such that a substantial portion of the light is transmitted in thecladding.

In other embodiments, break-lines are substantially parallel to eachother, with the first and second surfaces being opposed to each other onopposite sides of the fiber.

In still other embodiments, additional angled surfaces are added. Ineach case, the angled surfaces intersect the end surface at break-lines,preferably falling near the cladding-core interface.

In general, according to another aspect, the invention also relates to amethod for manufacturing a tip for an optical fiber. This processcomprises first cleaving an end surface in the fiber. At least first andsecond surfaces are then formed, angled relative to the end surface.

In the preferred embodiment, a spatial intensity profile of lightexiting from the tip is detected, which is used to monitor the polishingof the first and/or second angled surfaces.

The above and other features of the invention including various noveldetails of construction and combinations of parts, and other advantages,will now be more particularly described with reference to theaccompanying drawings and pointed out in the claims. It will beunderstood that the particular method and device embodying the inventionare shown by way of illustration and not as a limitation of theinvention. The principles and features of this invention may be employedin various and numerous embodiments without departing from the scope ofthe invention.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings, reference characters refer to the sameparts throughout the different views. The drawings are not necessarilyto scale; emphasis has instead been placed upon illustrating theprinciples of the invention. Of the drawings:

FIG. 1 is a cross-sectional side view of the inventive fiber tip;

FIG. 2 is an end view of the inventive fiber tip;

FIG. 2A is an end view of the inventive fiber tip showing the first andsecond break-lines passing over the core;

FIG. 3 is a side view illustrating the coupling between the laser andthe fiber when the optical axis of the laser is not parallel to theoptical axis of the fiber; and

FIGS. 4A-4C illustrate the steps for manufacturing the inventive fibertip.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 is a cross-sectional view showing a fiber tip or endfaceconstructed according to the principles of the present invention.

The single-mode optical fiber 100 has three surfaces fabricated on tip110. Planar surfaces S1 and S2 slant obliquely backward from theterminal end, on opposed sides of the fiber. The slopes of surfaces S1and S2 are identified as θ1 and θ2, respectively, measured from a planeextending perpendicularly to the mechanical and optical axis 112 of thefiber 100. Preferably, θ1 and θ2 are approximately 25°. A workable rangefor θ1 and θ2 is between 10 and 40°. In one implementation, one of θ1 orθ2 is more 25° and the other is less 25°. The third surface S3 isperpendicular to the mechanical and optical axis 112 of the fiber 100.

As best shown in FIG. 2, the angled surfaces S1 and S2 join the endsurface S3 at break-lines BL1 and BL2, respectively. These break-linespass near the edge of the fiber's core 102, or cladding-core interface,105.

In the illustrated embodiment, the angled surfaces S1-S2 oppose eachother on opposite sides of the fiber 100, and thus the break-lines BL1and BL2 are parallel to each other. It should be noted that thebreak-lines BL1 and BL2 need not be parallel to each other for allapplications. It may be desirable in some cases to configure the angledsurfaces S1 and S2 to not be directly opposed to each other.

Moreover, it is not necessary that the break-lines BL1-BL2 intersect orpass over the core 102 of the fiber 100. In the illustrated example, thebreak-lines BL1 and BL2 pass to the outside of cladding-core interface105. This configuration is typically used when the fiber mode'swavelength is sufficiently longer than the cut-off wavelength; asignificant portion of the mode will thus occupy the cladding region104.

FIG. 2A shows another embodiment in which the first and secondbreak-lines pass BL1 and BL2 pass over the core 102.

As illustrated by FIG. 3, angles θ1 and θ2 of surfaces S1 and S2 neednot be equal to each other. This might be necessary when the opticalaxis 210 of the light source 200 is not parallel to the optic axis ofthe fiber as illustrated. This is equivalent to having a tilted facet orlaser beam.

The present invention is not limited to elliptical core fibers orcircularly symmetric fibers. It can be used with elliptical clad, panda,elliptical core, bow-tie, tapered, and circularly symmetric fibers.Moreover, more than two angled surfaces may be formed at the tip 110 toachieve a more hyperbolic end, while still maintaining the perpendicularend surface S3. Still further, the fiber tip may have a dielectriccoating.

FIGS. 4A-4C illustrate the technique for manufacturing the inventivefiber tip.

As shown in FIG. 4A, the end 110 of the fiber 100 is flat cleaved. Thisstep is preferably performed using well-known fiber cleaving processes.

As shown in FIG. 4B, the surface S1 is then polished into the fiber. Theextent of the polishing and thus the extent of surface S1 is controlledin response to a pattern of light 310 exiting the fiber, which isproduced by injecting light into the opposite end. An intensity profile312 is monitored using photodetector 300. In the preferred embodiment,the photodetector is located remotely from and parallel to surface S3.The intensity is scanned in a direction perpendicular to break-line BL1in the plane of the photodetector 300 to plot the spatial intensityprofile 312.

The shape and location of the peak 314 in the spatial intensity profileis used to control the polishing of the surface. Generally, the locationof the peak's maxima 315 in a direction parallel to surface S3 isindicative of the location of the break-line BL1, and the peak's shapeor extent 318 is indicative of the angle θ1. Thus, the profile isdescriptive of the two variables in the machining of surface S1.

Generally, the polishing of surface S1 is controlled so that thelocation of the breakline BL1 either falls only over the cladding 104 orin some cases may also enter a portion of the core 102. This choicedepends generally on the frequency of light transmitted by the fiberrelative to the fiber's dimensions and thus to what extent the light istransmitted within the fiber's cladding 104.

As shown in FIG. 4C, in the next step, surface S2 is polished into thefiber tip. Again, the spatial intensity profile 312 on the detector 300is used to monitor polishing to achieve the desired location ofbreak-line BL2 and angle θ2 by reference to the maxima and breadth ofpeak 316.

Experience from manufacturing suggests that it is helpful to allow thefiber 100 to bend somewhat during the polishing process. It is theorizedthat this adds some curvature to surfaces S1 and S2 and rounds over thebreak-lines BL1 and BL2 achieving a more hyperbolic cross-section.

In other embodiments, additional, i.e., more than two, angled surfaces,such as a total of four, are polished into the fiber tip. Whileincreasing polishing steps, the tip better approximates a circularlyhyperbolic shape.

There are a number of advantages of the present invention relative tothe double-angled wedge-shaped fiber tip. First, the number ofindependent variables in the manufacture of the fiber is reduced tofour, the location of the break-lines and the angles of surfaces S1 andS2. There are seven independent variables in the manufacture of thedouble-angled wedge-shaped angle tip. Additionally, the cleaved surfaceS3 is not subjected to polishing and therefore retains the superioroptical properties of a smooth, cleaved surface relative to a polishedsurface.

While this invention has been particularly shown and described withreferences to preferred embodiments thereof, it will be understood bythose skilled in the art that various changes in form and detail may bemade therein without departing from the spirit and scope of theinvention as defined by the appended claims.

What is claimed is:
 1. A method for manufacturing a tip for an opticalfiber including a core and surrounding cladding for transmittingelectromagnetic radiation along an axis of the fiber, the processcomprising:cleaving an end surface in the fiber; polishing a firstangled surface, which defines a first break-line at an intersectionbetween the first angled surface and the end surface, until thebreak-line falls near an edge of the core; and polishing a second angledsurface, which defines a second break-line at an intersection betweenthe second angled surface and the end surface, until the secondbreak-line falls near the edge of the core, wherein the tip is installedin proximity to a semiconductor laser source to collect light therefrom.2. The method described in claim 1, further comprising:detecting aspatial intensity profile of light exiting from the tip; and using thespatial intensity profile to monitor the polishing of the first and/orsecond angled surfaces.
 3. The method described in claim 1, wherein thefiber is cleaved so that the end surface is substantially orthogonal toan axis of the fiber.
 4. The method described in claim 1, furthercomprising polishing the first and second angled surfaces at differentangles relative to an axis of the fiber.
 5. The method described inclaim 1, further comprising polishing the first and second angledsurfaces at the same angle relative to an axis of the fiber.
 6. A methodfor manufacturing a tip for an optical fiber including a core andsurrounding cladding for transmitting electromagnetic radiation along anaxis of the fiber, the process comprising:cleaving an end surface in thefiber; thereafter polishing a first angled surface, which defines afirst break-line at an intersection between the first angled surface andthe end surface, until the break-line falls near an edge of the core;and thereafter polishing a second angled surface, which defines a secondbreak-line at an intersection between the second angled surface and theend surface, until the second break-line falls near the edge of thecore, wherein the tip is installed in proximity to a semiconductor lasersource to collect light therefrom.
 7. The method described in claim 6,further comprising:detecting a spatial intensity profile of lightexiting from the tip; and using the spatial intensity profile to monitorthe polishing of the first and/or second angled surfaces.
 8. The methoddescribed in claim 6, wherein the fiber is cleaved so that the endsurface is substantially orthogonal to an axis of the fiber.
 9. Themethod described in claim 6, further comprising polishing the first andsecond angled surfaces at different angles relative to an axis of thefiber.
 10. The method described in claim 6, further comprising polishingthe first and second angled surfaces at the same angle relative to anaxis of the fiber.
 11. The method described in claim 6, furthercomprising polishing the first and second angled surfaces at the sameangle relative to an axis of the fiber.